Effect of bio-based polyols and chain extender on the microphase separation structure, mechanical properties and morphology of rigid polyurethane foams
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[1] Jianhai Yang,et al. An unparalleled H-bonding and ion-bonding crosslinked waterborne polyurethane with super toughness and unprecedented fracture energy. , 2021, Materials horizons.
[2] Yu-Zhong Wang,et al. Flame-retarded thermoplastic polyurethane elastomer: From organic materials to nanocomposites and new prospects , 2021 .
[3] Darren J. Martin,et al. Valorisation of Technical Lignin in Rigid Polyurethane Foam: A Critical Evaluation on Trends, Guidelines and Future Perspectives , 2021, Green Chemistry.
[4] C. Du,et al. In Situ Determination of Nitrate in Water Using Fourier Transform Mid-Infrared Attenuated Total Reflectance Spectroscopy Coupled with Deconvolution Algorithm , 2020, Molecules.
[5] M. Merzouki,et al. Spectroscopic characterization of organic matter transformation during composting of textile solid waste using UV–Visible spectroscopy, Infrared spectroscopy and X-ray diffraction (XRD) , 2020, Microchemical Journal.
[6] Yu-Zhong Wang,et al. Novel piperazine-containing oligomer as flame retardant and crystallization induction additive for thermoplastics polyurethane , 2020 .
[7] Qinqin Zhang,et al. The Degradation and Repolymerization Analysis on Solvolysis Liquefaction of Corn Stalk , 2020, Polymers.
[8] Guangyu Zhang,et al. Anti-flammability, mechanical and thermal properties of bio-based rigid polyurethane foams with the addition of flame retardants , 2020, RSC advances.
[9] I. Joye,et al. Peak Fitting Applied to Fourier Transform Infrared and Raman Spectroscopic Analysis of Proteins , 2020, Applied Sciences.
[10] Xinwen Peng,et al. Edge activation of an inert polymeric carbon nitride matrix with boosted absorption kinetics and near-infrared response for efficient photocatalytic CO2 reduction , 2020 .
[11] Xiaoxuan Liu,et al. A healable waterborne polyurethane synergistically cross-linked by hydrogen bonds and covalent bonds for composite conductors , 2020, Journal of Materials Chemistry C.
[12] F. Gao,et al. A high stiffness and self-healable polyurethane based on disulfide bonds and hydrogen bonding , 2020 .
[13] Jin Zhu,et al. Reexamination of the microphase separation in MDI and PTMG based polyurethane: Fast and continuous association/dissociation processes of hydrogen bonding , 2019 .
[14] H. Tian,et al. Measuring the Microphase Separation Scale of Polyurethanes with a Vibration-Induced Emission-Based Ratiometric "Fluorescent Ruler". , 2019, ACS applied materials & interfaces.
[15] Chi-Hui Tsou,et al. Synthetic Environmentally Friendly Castor Oil Based-Polyurethane with Carbon Black as a Microphase Separation Promoter , 2019, Polymers.
[16] R. Verdejo,et al. Thermo-reversible crosslinked natural rubber: A Diels-Alder route for reuse and self-healing properties in elastomers , 2019, Polymer.
[17] Xiaofei Yan,et al. Liquefaction of Peanut Shells with Cation Exchange Resin and Sulfuric Acid as Dual Catalyst for the Subsequent Synthesis of Rigid Polyurethane Foam , 2019, Polymers.
[18] M. Kamkar,et al. Nanoparticle effects of thermoplastic polyurethane on kinetics of microphase separation, with or without preshear , 2018 .
[19] C. Du,et al. Investigation of soil properties using different techniques of mid‐infrared spectroscopy , 2018, European Journal of Soil Science.
[20] L. Avérous,et al. Renewable polyols for advanced polyurethane foams from diverse biomass resources , 2018 .
[21] Yongri Liang,et al. Multiphase Structure and Electromechanical Behaviors of Aliphatic Polyurethane Elastomers , 2018, Macromolecules.
[22] J. Clark,et al. Renewable Self-Blowing Non-Isocyanate Polyurethane Foams from Lysine and Sorbitol , 2018, European Journal of Organic Chemistry.
[23] J. Chen,et al. Asynchronous fracture of hierarchical microstructures in hard domain of thermoplastic polyurethane elastomer: Effect of chain extender , 2018 .
[24] Weiliang Zhou,et al. Self‐healing polyurethane based on disulfide bond and hydrogen bond , 2018 .
[25] A. Hejna,et al. The Study on Application of Biopolyols Obtained by Cellulose Biomass Liquefaction Performed with Crude Glycerol for the Synthesis of Rigid Polyurethane Foams , 2018, Journal of Polymers and the Environment.
[26] R. S. Walia,et al. PU foam derived from renewable sources: Perspective on properties enhancement: An overview , 2017 .
[27] Arthur J. Ragauskas,et al. Recent advances in lignin-based polyurethanes , 2017 .
[28] S. Caillol,et al. A perspective approach to sustainable routes for non-isocyanate polyurethanes , 2017 .
[29] W. Liu,et al. A Multiscale Investigation on the Mechanism of Shape Recovery for IPDI to PPDI Hard Segment Substitution in Polyurethane , 2016 .
[30] Chul B. Park,et al. CO2-blown microcellular non-isocyanate polyurethane (NIPU) foams: from bio- and CO2-sourced monomers to potentially thermal insulating materials , 2016 .
[31] B. Weckhuysen,et al. Unlocking the potential of a sleeping giant: lignins as sustainable raw materials for renewable fuels, chemicals and materials , 2015 .
[32] Xinya Zhang,et al. The structure, microphase-separated morphology, and property of polyurethanes and polyureas , 2014, Journal of Materials Science.
[33] Yebo Li,et al. Two-step sequential liquefaction of lignocellulosic biomass by crude glycerol for the production of polyols and polyurethane foams. , 2014, Bioresource technology.
[34] Gerald A. Tuskan,et al. Lignin Valorization: Improving Lignin Processing in the Biorefinery , 2014, Science.
[35] Yanhua Jiang,et al. Highly recoverable rosin-based shape memory polyurethanes , 2013 .
[36] B. Fernández-d'Arlas,et al. Molecular Engineering of Elastic and Strong Supertough Polyurethanes , 2012 .
[37] M. Sultan,et al. Preparation and characterization of rigid polyurethane foam prepared from sugar-cane bagasse polyol , 2011 .
[38] H. Pan. Synthesis of polymers from organic solvent liquefied biomass: A review , 2011 .
[39] J. M. Sands,et al. Morphology control of segmented polyurethanes by crystallization of hard and soft segments , 2010 .
[40] Prasant Kumar Rout,et al. Production of first and second generation biofuels: A comprehensive review , 2010 .
[41] J. Runt,et al. A Comparison of Phase Organization of Model Segmented Polyurethanes with Different Intersegment Compatibilities , 2008 .
[42] York Neubauer,et al. Direct Liquefaction of Biomass , 2008 .
[43] K. Caba,et al. Microdomain composition and properties differences of biodegradable polyurethanes based on MDI and HDI , 2008 .
[44] Paul C. Painter,et al. A Comparison of Hydrogen Bonding and Order in a Polyurethane and Poly(urethane−urea) and Their Blends with Poly(ethylene glycol) , 2007 .
[45] Ruth E. Cameron,et al. A review of small-angle scattering models for random segmented poly(ether-urethane) copolymers , 2004 .
[46] I. Yilgor,et al. Hydrogen bonding and polyurethane morphology. I. Quantum mechanical calculations of hydrogen bond energies and vibrational spectroscopy of model compounds , 2002 .
[47] K. Wei,et al. Hydrogen bonding and mechanical properties in segmented montmorillonite/polyurethane nanocomposites of different hard segment ratios , 2001 .
[48] S. Cooper,et al. Microphase Separation and Rheological Properties of Polyurethane Melts. 2. Effect of Block Incompatibility on the Microstructure , 2000 .
[49] S. Cooper,et al. Microphase separation and rheological properties of polyurethane melts. 1. Effect of block length , 1998 .
[50] H. Lee,et al. Spectroscopic analysis of phase separation behavior of model polyurethanes , 1987 .
[51] N. Schneider,et al. Infrared Studies of Hydrogen Bonding in Toluene Diisocyanate Based Polyurethanes , 1975 .
[52] S. Cooper,et al. Infrared Studies of Segmented Polyurethan Elastomers. I. Hydrogen Bonding , 1970 .
[53] Y. Yamaguchi,et al. Quantitative study on hydrogen bonding between urethane compound and ethers by infrared spectroscopy , 1968 .